Mating type in filamentous ascomycetes is controlled by idiomorphic alleles, named MAT1-1 and MAT1-2, which contain 1-3 genes. Of these genes MAT1-1-1 and MAT1-2-1 encode putative transcription factors and are thus considered to be the major regulators of sexual communication and mating. Fungi with no known sexual stage may also have fully functional mating type genes and therefore it was plausible to hypothesize that the MAT products may also regulate other types of genes not involved directly in the mating process. To identify putative target genes of these transcription factors in Fusarium verticillioides, DMAT1-2-1 knock out mutants were produced and transcript profiles of mutant and wild type were compared by means of differential cDNA hybridization. Clones, either up-or down-regulated in the DMAT1-2-1 mutant were sequenced and a total of 248 sequences were blasted against the NCBI database as well as the Gibberella zeae and Gibberella moniliformis genomes. Fifty-five percent of the clones were down-regulated in the mutant, indicating that the MAT1-2-1 product positively affected these tagged sequences. On the other hand, 45% were found to be up-regulated in the mutant, suggesting that the MAT1-2-1 product also exerted a negative regulatory function on this set of genes. Sequences involved in protein synthesis and metabolism occurred more frequently among the clones up-regulated in the mutant, whereas genes belonging to cell signalling and communication were especially frequently tagged among the sequences down-regulated in the mutant.
Sex in fungi is regulated by highly dissimilar mating type loci named idiomorphs. The genus Fusarium harbours both sexual as well as esexual species and each appears to contain one or the other idiomorph. The structure of these loci is highly conserved, suggesting a cryptic sexual cycle in these socalled asexual species. Alternatively, idiomorphs could regulate additional hitherto unrecognized biological processes. Such processes could be elucidated by expression profiling using mutants disrupted in their mating type loci.
Fpmtr1, an amino acid transporter gene from Fusarium proliferatum was strongly expressed during conidial germination and repressed in late stationary phase. To identify the specific function of this gene, DeltaFpmtr1 knock-out mutants were generated by gene replacement. Vegetative growth of the DeltaFpmtr1 mutants was normal both in liquid and on solid media, but conidial germination was delayed. The DeltaFpmtr1 mutants and the wild type were equally fertile when used as males in sexual crosses, however if the mutants were used as the female parent then the fertility of the cross decreased dramatically. Inactivation of Fpmtr1 abolished vegetative self-incompatibility in strain ITEM 2287 of F. proliferatum, but the DeltaFpmtr1 mutants were still vegetatively incompatible with the other strains of the fungus. Endophytic colonization capability of the mutants, assessed on maize seedlings also was adversely affected. These data suggest that Fpmtr1 is involved in multiple developmental processes related to both sexual and parasexual events in F. proliferatum. Furthermore, the fungus might have problems in adapting to a less than optimal environment if this otherwise dispensable transporter has been inactivated.
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